Nickel diatomaceous earth catalyst and method for producing the same

ABSTRACT

A nickel diatomaceous earth catalyst having a weight loss rate measured by hydrogen-TG at 400 to 600° C. of 0.05 to 2.0%.

TECHNICAL FIELD

The present invention relates to a nickel diatomaceous earth catalystand a method for producing the same.

BACKGROUND ART

Hydrogenation reaction using an ammonia solvent has been widelyconducted and a typical example thereof may include synthesis of aminesfrom nitriles. While nickel, cobalt, platinum, palladium, rhodium andthe like are used as a catalyst for the hydrogenation reaction, nickelis widely used in terms of cost and hydrogenation performance.

Common methods for producing a nickel catalyst include, for example, animpregnation method in which pores of a molding support are impregnatedwith a nickel-containing solution, which is fixed to pore walls and thendried and calcined to support active components, and a precipitationmethod in which precipitates of hydroxide, carbonate or the like aregenerated by bringing an aqueous solution of a nickel component incontact with a precipitant solution, which is then filtered, washed withwater, dried, molded, and calcined. The precipitation method is suitablefor preparing a multicomponent catalyst or a catalyst having a highsupported ratio (20 to 40 wt %).

In the precipitation method, which is one of the methods for producingthe nickel catalyst, essential characteristics of the catalyst aredetermined at a stage where precipitation reaction occurs, and anactivation process after that stage is a stage for the catalyst toeffectively exhibit its characteristics. Thus, it is difficult to modifycatalytic performance after the precipitation reaction stage.

Catalytic activity and selectivity gradually decrease with use of thecatalyst, which results in deterioration of catalytic activity. One ofthe causes for this activity deterioration is catalytic sintering. Asintering rate depends on an amount of supported metals, a size ofmetallic particles, a kind of a support, a reaction condition, and thelike. As for the case of a metallic catalyst in general, it is effectiveto use a method in which crystallites of catalytic activity componentsare supported on a support having high heat resistance in a highlydispersed manner.

It has been known that heat resistance of the nickel catalyst in liquidammonia and under a hydrogen atmosphere is low. Non-Patent Literature 1,for example, describes the heat resistance of the nickel catalystsupported on γ-alumina in the liquid ammonia and under the hydrogenatmosphere. It is stated that when the nickel catalyst is heat-treatedat 110° C. to 150° C., no sintering occurs under the hydrogen atmospherealone or under the ammonia atmosphere alone, but the sintering occurswhen both hydrogen and ammonia are present simultaneously.

As a conventional precipitation method, Patent Literature 1, forexample, describes a method in which a precursor produced byprecipitating a compound containing nickel hydroxide and nickelcarbonate on the surface of the support using the precipitation methodis heat-treated with steam to produce a nickel catalyst excellent inboth hydrogenation activity and heat resistance.

CITATION LIST Patent Literature

-   Patent Literature 1: Japanese Patent Laid-Open No. 2012-30169

Non-Patent Literature

-   Non-Patent Literature 1: Johan Lif, Magnus Skoglundh, Lars    Lowendahl. “Sintering of nickel particles supported on γ-alumina in    ammonia”, Applied Catalysis A: General, Volume 228, Issues 1-2,    2002, P. 145-154

SUMMARY OF INVENTION Technical Problem

Although the method described in Patent Literature 1 is effective forpreventing a decrease in a surface area when the catalyst is heated at800° C., it is uncertain whether or not the method is effective inimproving the heat resistance of the catalyst in the liquid ammonia andunder the hydrogen atmosphere.

An object of the present invention is to provide a nickel diatomaceousearth catalyst having excellent heat resistance during hydrogenationreaction using an ammonia solvent, and a method for producing such anickel diatomaceous earth catalyst.

Solution to Problem

The present inventors have conducted an extensive research to achievethe above-mentioned object and made the following findings to solve theproblem.

That is, the present invention is as follows.

[1]

A nickel diatomaceous earth catalyst having a weight loss rate measuredby hydrogen-TG at 400 to 600° C. of 0.05 to 2.0%.

[2]

The nickel diatomaceous earth catalyst according to the above [1],wherein a nickel crystallite diameter is 30 to 100 Å.

[3]

The nickel diatomaceous earth catalyst according to the above [1] or[2], wherein a change A in the nickel crystallite diameter betweenbefore and after a heat resistance test is 210 Å or less.

[4]

The nickel diatomaceous earth catalyst according to any of the above [1]to [3], wherein the nickel diatomaceous earth catalyst has a specificsurface area of 60 to 180 m²/g.

[5]

A method for producing a nickel diatomaceous earth catalyst using aprecipitation method,

wherein the method comprises the steps of:

adding an alkaline solution as a precipitant to a dispersion liquid inwhich diatomaceous earth and a salt of a nickel catalyst are mixed; and

performing a drying treatment, a calcination treatment, and a reductiontreatment, in this order,

wherein the reduction treatment is performed at a peak temperature +40°C. or more of a hydrogen-TPR measurement on a calcined powder producedby the calcination treatment.

[6]

The method for producing a nickel diatomaceous earth catalyst accordingto the above [5], wherein the reduction treatment is performed at thepeak temperature +200° C. or less of the hydrogen-TPR measurement on thecalcined powder produced by the calcination treatment.

[7]

A nickel diatomaceous earth catalyst produced by the method according tothe above [5] or [6].

[8]

A method for producing xylylenediamine, wherein the method compriseshydrogenating phthalonitrile in an ammonia solvent by using the nickeldiatomaceous earth catalyst according to any of the above [1] to [4] and[7].

Advantageous Effects of Invention

The nickel diatomaceous earth catalyst of the present invention exhibitsexcellent heat resistance during the reaction with the liquid ammoniaand under the hydrogen atmosphere. Accordingly, the catalyst can be usedfor the reaction at high temperatures, which can extend a life of thecatalyst.

DESCRIPTION OF EMBODIMENTS

Hereinafter, a mode for carrying out the present invention (hereinafter,referred to as “the present embodiment”) is described in detail. Thepresent embodiment mentioned below is only an example for describing thepresent invention and is not intended to limit the present invention tothe following descriptions. The present invention can be carried out bymaking modifications as appropriate within the outlined range.

In the present embodiment, each physical property can be measured inaccordance with the method described in Examples below.

[Catalyst]

A nickel diatomaceous earth catalyst according to the present embodimenthas a weight loss rate measured by hydrogen-TG at 400 to 600° C. of 0.05to 2.0%. The weight loss rate measured by hydrogen-TG at 400 to 600° C.is preferably 0.1 to 1.8%, more preferably 0.1 to 1.0%. When the weightloss rate measured by hydrogen-TG at 400 to 600° C. is less than 0.05%,reduction needs to be carried out under severe conditions, which isdisadvantageous in terms of cost efficiency and safety. The weight lossrate of more than 2.0%, on the other hand, provides the catalyst withpoor heat resistance.

A specific surface area of the nickel diatomaceous earth catalystaccording to the present embodiment is preferably 50 to 180 m²/g, morepreferably 60 to 180 m²/g, further preferably 60 to 170 m²/g. When thespecific surface area of the catalyst is 50 m²/g or more, the catalysttends to exhibit excellent hydrogenation performance. When the specificsurface area is 180 m²/g or less, the catalyst tends to have excellentheat resistance.

A nickel crystallite diameter of the nickel diatomaceous earth catalystaccording to the present embodiment is preferably 20 to 250 Å, morepreferably 30 to 100 Å, further preferably 30 to 80 Å. When the nickelcrystallite diameter of the catalyst is 20 Å or more, the heatresistance in liquid ammonia and under a hydrogen atmosphere tends to beimproved. When the nickel crystallite diameter is 250 Å or less, thehydrogenation performance tends to be improved.

A change A in the nickel crystallite diameter between before and after aheat resistance test of the nickel diatomaceous earth catalyst accordingto the present embodiment is preferably 210 Å or less, more preferably160 Å or less, further preferably 100 Å or less, in terms of the heatresistance.

The heat resistance test mentioned above refers to the heat resistancetest described in Examples below.

The nickel diatomaceous earth catalyst according to the presentembodiment may contain one or more components selected from the groupconsisting of Li, Na, K, Rb, Cs, Be, Ca, Sr, Ba, Ti, Cu, Cr, Zn, Mn, Mg,Ga, Ge, Nb, Ir, Pt, Bi, Al, In, Sr, Ce, Co, and Mo.

[Production Method]

A method for producing a nickel diatomaceous earth catalyst according tothe present embodiment uses a precipitation method, the method includingthe steps of:

adding an alkaline solution as a precipitant to a dispersion liquid inwhich diatomaceous earth and a salt of a nickel catalyst are mixed; and

performing a drying treatment, a calcination treatment, and a reductiontreatment. The reduction treatment is performed at a peak temperature+40° C. or more of a hydrogen-TPR measurement on a calcined powderproduced by the calcination treatment.

The precipitation method is not limited to a particular method as longas a compound containing nickel hydroxide and nickel carbonate isdeposited on a surface of the diatomaceous earth, and any of theconventionally known methods can be employed.

[Precipitation Treatment]

When preparing the dispersion liquid in which the diatomaceous earth andthe salt of a nickel catalyst are mixed, the diatomaceous earth may beadded to the solvent or the solvent may be added to the diatomaceousearth. When adding one to another, for example, the diatomaceous earthmay be added to the solvent at 0 to 40° C., which is stirred for 30 to60 minutes and then heated to a predetermined temperature, or thediatomaceous earth may be added to the solvent which has been heated tothe predetermined temperature.

The salt of a nickel catalyst is not limited to a particular salt andexamples thereof include nickel sulfate and nickel nitrate.

The alkaline solution as a precipitant is not limited to the particularone and examples thereof include an alkaline solution in which acarbonate such as sodium carbonate or sodium bicarbonate is dissolved.Into a dispersion liquid produced by adding a solution of a salt of thenickel catalyst to a solution in which the diatomaceous earth isdispersed, the alkaline solution as a precipitant may be poured using atube pump or the like.

Pouring of the alkaline solution as a precipitant may be performed byeither a regular pouring or a reverse pouring, but generally the methodin which the alkaline solution as a precipitant is poured into thesolution of a salt of a nickel catalyst (regular pouring method) isused. When the nickel catalyst is used, a precursor having a compoundcontaining nickel hydroxide and nickel carbonate deposited on thesurface of the diatomaceous earth can be produced. When a nickel sourceis nickel nitrate and an alkali source is sodium carbonate, theprecipitation reaction is represented by the following formula (1), andas a result of the reaction, basic nickel carbonate is produced.

(Formula 1)

Ni(NO₃)₂+Na₂CO₃ →mNi(OH)₂.NiCO+NaNO₃  (1)

A molar ratio of alkali to nickel is preferably 1 to 4, more preferably1.5 to 3. When the molar ratio of alkali to nickel falls within theabove range, a precipitation pH is approximately 8 to 9. Accordingly,precipitation and deposition on the diatomaceous earth of basic nickelcarbonate are more likely to occur.

When the alkaline solution as a precipitant is poured into thedispersion liquid of a catalyst component-containing solution in whichthe diatomaceous earth and the salt of a nickel catalyst are dissolved(hereinafter, referred to as “mother liquid”), the mother liquid ispreferably maintained at 50 to 90° C., more preferably 60 to 80° C.Generating precipitates at a time of heating the mother liquid is morelikely to make a particle diameter of precipitated particles uniform.

When a precipitation temperature is low, precipitated particles aregenerated slowly, and thus highly active catalytic precipitates are morelikely to be produced. When the precipitation temperature is high,precipitates are produced in a short time, which can shorten aproduction process and also precipitated particles with small and evensize can be produced.

When pouring the alkaline solution as a precipitant, it is preferablethat the mother liquid is stirred. As a surface of generatedprecipitated particles has an agglomeration force acting amongparticles, stirring of the mother liquid can prevent an aggregate fromgrowing large.

A length of time for pouring the precipitant is preferably 30 to 120minutes, more preferably 60 to 90 minutes. It is preferable that heatingand stirring are performed for a while after pouring so that aging ofthe precipitates proceeds. Changing an aging temperature can change thecatalytic performance. The aging temperature may be either higher orlower than a pouring temperature and is preferably 50 to 90° C., morepreferably 60 to 80° C., from the viewpoint of producing basic nickelcarbonate from a generated precipitated component. An aging time ispreferably about 0 to 3 hours, more preferably 0.5 to 2 hours, in termsof a time for basic nickel carbonate to be deposited and fixed on thediatomaceous earth.

As for the diatomaceous earth, a calcined product or a non-calcinedproduct may be used. These products may be used singly or mixed togetherto achieve predetermined physical properties. However, with the calcinedproduct alone, basic nickel carbonate is less likely to be deposited onthe diatomaceous earth, which is more likely to end up producing areadily reducible catalyst. With the non-calcined product alone, basicnickel carbonate is readily deposited on the diatomaceous earth, whichis more likely to end up producing a hardly reducible catalyst. When anappropriate reducibility is determined, an amount of basic nickelcarbonate deposited on the diatomaceous earth is estimated from anamount of Si eluted in the treatment by the alkaline solution as aprecipitant. An appropriate compounding ratio is determined by using thecalcined product or the non-calcined product alone, or a mixture of bothproducts.

For example, the amount of Si eluted when the diatomaceous earth isstirred at 80° C. for 2 hours using a 10% Na₂CO₃ aqueous solution ispreferably 0.5 to 1.5%, more preferably 0.7 to 1.1%. When mixing thediatomaceous earth, the Na₂CO₃ aqueous solution may be added after thecalcined product and the non-calcined product are mixed, or the calcinedproduct and the non-calcined product of the diatomaceous earth may beseparately added to the solution. As conditions for mixing, for example,the diatomaceous earth may be added to the solution of 10 to 40° C.,which is stirred for 30 to 60 minutes and then heated to a predeterminedtemperature, or the diatomaceous earth may be added to the solutionwhich has been heated to the predetermined temperature.

When the diatomaceous earth is used alone, changing an aging timedepending on a kind of the diatomaceous earth can control thereducibility. For example, when the calcined product is used, a longeraging time is recommended as it is more likely to provide a readilyreducible product. When the non-calcined product is used, a shorteraging time is recommended as it is more likely to provide a hardlyreducible product.

Further, changing the aging temperature can also control thereducibility. For example, when the calcined product is used, a higheraging temperature is recommended as it is more likely to provide areadily reducible product. When the non-calcined product is used, alower aging temperature is recommended as it is more likely to provide ahardly reducible product.

[Washing, Filtration, and Drying Treatment]

The precipitates produced by the precipitation treatment may besubjected to washing, filtration, and drying by a commonly used method.For example, the precipitates can be collected using Nutsche and furtherwashed with water or the like to eliminate impurity ions (such as SO₄ ²⁻and NO₃ ⁻). A nickel compound is easily bonded to S and N, and thus ishazardous as such bonding may produce a causative substance ofpoisoning. As for washing, a filtered cake once produced by thefiltration is suspended in water and stirred to wash in suspension. Theelectrical conductivity of filtrate after washing in suspension ispreferably set at 1 mS/cm or less. The filtered cake after being washedis fully dried at around 100° C. to produce a dried cake.

[Calcination Treatment]

The dried cake may be calcined by a commonly used method. For example,the calcination treatment is performed using an electric furnace. Acalcination atmosphere may be provided with air or nitrogen. Acalcination temperature is preferably 200 to 500° C., more preferably350 to 450° C., in terms of the temperature at which nickel hydroxide ornickel carbonate is decomposed. A calcination time is preferably 3 to 10hours, more preferably 5 to 7 hours, in terms of a time required tofully decompose nickel hydroxide or nickel carbonate. When thecalcination treatment is performed on basic nickel carbonate, thermaldecomposition is occurred as represented by the following formula (2),and nickel oxide (calcined powder) is produced.

(Formula 2)

mNi(OH)₂ +nNiCO₃→(m+n)NiO+mH₂O+nCO₂  (2)

The catalyst reducibility is studied by performingtemperature-programmed reduction with hydrogen (hydrogen-TPRmeasurement) on the calcined powder. A peak temperature of thehydrogen-TPR measurement is preferably 200 to 500° C., more preferably300 to 400° C., further preferably 300 to 360° C. The nickel catalystprepared by the above method is in a state of an oxidative product andexhibits no catalytic activity in that state.

[Reduction Treatment]

After the calcination treatment, the reduction treatment is performed toactivate the catalyst (refer to the following formula (3)). As areductant used in this case, commonly used reductants such as hydrogen,carbon monoxide, and methanol may be used. Hydrogen is preferably usedin terms of toxicity and easy handling. For example, a certain amount ofthe catalyst after calcination is placed in a reaction tube made of SUS,which is heated under a nitrogen atmosphere, and hydrogen gas isintroduced into the reaction tube. The reaction temperature ispreferably 350 to 500° C., more preferably 380 to 450° C.

Although an amount of an unreduced nickel compound can be reduced byperforming the reduction reaction at a higher temperature, a specificsurface area becomes small and activity tends to deteriorate when thetemperature is too high. Additionally, raising the temperature requirestime and energy, and thus is not cost-effective and also increases arisk.

(Formula 3)

NiO+H₂→Ni+H₂O  (3)

The acceleration of sintering is attributed to the nickel compoundremaining unreduced (unreduced nickel compound). To perform reduction insuch a manner that less unreduced nickel compounds are produced, areduction treatment temperature is set higher than a peak temperature ofthe temperature-programmed reduction with hydrogen (hydrogen-TPRmeasurement) performed on the calcined powder produced by thecalcination treatment. More specifically, the reduction treatmenttemperature is performed at a peak temperature +40° C. or more,preferably at a peak temperature +50° C. or more, more preferably at apeak temperature +60° C. or more, of the hydrogen-TPR measurement on thecalcined powder. An upper limit of the reduction treatment temperatureis not limited to a particular temperature and is performed preferablyat a peak temperature +200° C. or less, more preferably at a peaktemperature +150° C. or less, further preferably at a peak temperature+100° C. or less, of the hydrogen-TPR measurement on the calcinedpowder, from the viewpoint of preventing a decrease in the catalyticactivity.

After the reduction reaction, the nickel catalyst is cooled down to roomtemperature under a nitrogen atmosphere and stabilized. When theactivated nickel catalyst is exposed to air, it causes sudden oxidativeheat generation which leads to deterioration of the activity. For thatreason, it is necessary to pay a careful attention not to expose thecatalyst to the outside air and also necessary to pay a carefulattention to a preserving period when keeping and handling the catalyst.To maintain the catalytic performance, a surface of the reduced nickelis subjected to partial oxidization at a low temperature or adsorptionwith inert gas such as carbon dioxide and nitrogen to protect thesurface, or, depending on applications, the catalyst is dispersed in asolvent such as oil for protection of the surface.

One or more components selected from the group consisting of Li, Na, K,Rb, Cs, Be, Ca, Sr, Ba, Ti, Cu, Cr, Zn, Mn, Mg, Ga, Ge, Nb, Ir, Pt, Bi,Al, In, Sr, Ce, Co, and Mo can be added to the catalyst as necessary. Asa method for adding the components, aqueous solutions of each componentand a nickel salt solution may be mixed first and a precipitant may bepoured into the mixture to produce the precipitates, or a certain amountof compounds of each component may be added to the precipitates producedby the washing and filtration treatment.

A shape of the catalyst is not limited to a particular shape and may bemolded into a required shape and size according to the condition of use.For example, when high mechanical strength is required for catalystparticles or when sufficient strength cannot be gained by other moldingmethods, a compression molding method can be used. In the compressionmolding method, for example, graphite may be added to mold the catalystinto the form of pellet by means of tablet molding. When high mechanicalstrength is not required, an extrusion molding method which is excellentin productivity and continuous production can be used. When this methodis used, an inorganic binder may be added as a strength improver.Examples of the inorganic binder include clay minerals such as kaolinand montmorillonite; silica sol; and alumina sol. A particle diameter ofthe nickel catalyst after the molding process is preferably about 0.1 mmto 10 mm.

The nickel diatomaceous earth catalyst according to the presentembodiment can be used for all hydrogenation reactions in an ammoniasolvent. For example, by hydrogenating phthalonitrile, isophthalonitrile(IPN), terephthalonitrile (TPN), or a mixture of isophthalonitrile andterephthalonitrile (IPN/TPN) in the ammonia solvent, xylylenediamine,meta-xylylenediamine (MXDA), para-xylylenediamine (PXDA), of a mixtureof meta-xylylenediamine and para-xylylenediamine (MXDA/PXDA) can beproduced.

EXAMPLES

Hereinafter, the present embodiment is described in detail withreference to the following Examples. However, the present embodiment isnot limited only to the following Examples.

Measurement methods and evaluation methods for each physical property inExamples and Comparative Examples are as follows.

[Measurement of Physical Properties]

Physical properties of the dried cake were measured. The dried cake waspounded in a mortar and subsequently filtered through a 60 to 80 meshscreen to produce a dried powder, which was used as a measurementsample. As to the measurement of a specific surface area, a specificsurface area analyzer (NOVA 4200e manufactured by QuantachromeInstruments) was used. After the measurement sample was pretreated bydrying at 100° C. for 5 hours, the specific surface area was measured bya nitrogen adsorption measurement (BET method).

Next, physical properties of calcined powder were measured. A specificsurface area was measured in the same manner as described above.

A nickel metal surface area was calculated by measuring an amount ofhydrogen adsorption of a reduced catalyst using a method describedbelow. BELCAT-B (manufactured by BEL Japan, Inc.) was used as ameasuring device. First, about 0.4 g of the calcined powder was placedin a U-shaped glass tube. Into the reaction tube with an innertemperature being set at 340° C., helium (50 mL/min) was introduced for45 minutes followed by hydrogen (50 mL/min) for 30 minutes to reduce thecatalyst with hydrogen. Next, while keeping the reduced catalyst in theU-shaped glass tube, helium (50 mL/min) was introduced thereinto for 10minutes and left to cool down to room temperature. After that, whilekeeping the reduced catalyst in the U-shaped glass tube, hydrogen gas(50 mL/min) was repeatedly introduced for 1 minute and a hydrogenconcentration of discharged gas was measured by gas chromatography. Thehydrogen gas was pulsed until there was no increase or decrease in thehydrogen concentration at the inlet and outlet of the U-shaped tube, andthe nickel metal surface area was calculated based on the amount ofadsorption.

Reduction behavior was measured by the hydrogen-TPR. BELCAT-A(manufactured by BEL Japan, Inc.) was used as a measuring device. 0.1 gof the calcined powder was placed in the reaction tube, an innertemperature of the tube was set at 200° C., and then helium (50 mL/min)was introduced thereinto for 30 minutes. After that, the flowing gas wasswitched to 10% hydrogen/90% argon (50 mL/min) and heated to 800° C. ata heating rate of 2° C./min, and the reducibility at this time wasmeasured from a hydrogen consumption to calculate a peak temperature ofthe hydrogen-TPR.

Next, physical properties of a reduced and stabilized product weremeasured. The product was pounded in a mortar and subsequently filteredthrough a 60 to 80 mesh screen to produce a powder, which was used as ameasurement sample.

A specific surface area was measured in the same manner as describedabove.

The reduction behavior was measured by thermogravimetry (TG). Adifferential thermogravimetric analyzer (Thermo plus evo TG8120manufactured by Rigaku Corporation) was used as a measuring device.About 10 mg of the reduced and stabilized product was put into thedevice and 3% hydrogen/97% nitrogen (50 mL/min) was introduced. Thetemperature was raised to 600° C. at the heating rate of 10° C./min, anda weight loss rate at a high temperature range of 400 to 600° C. wasmeasured at this time. The weight loss rate is considered to indicatedesorption of the oxygenated compound from the unreduced nickel and is areference index indicating an amount of the unreduced nickel.

[Heat Resistance Test]

Heat resistance of the catalyst in liquid ammonia and under a hydrogenatmosphere was evaluated. After 0.4 g of the reduced and stabilizedproduct (60 to 80 mesh) was placed in a reaction tube made of SUS havingan inner diameter of 6 mm, an inner temperature of the reaction tube wasset at 250° C. and hydrogen (40 mL/min) was introduced thereinto for 10hours to produce a reduced catalyst. After that, in the reaction tube,an inner pressure was set at hydrogen 10 MPaG, the inner temperature wasset at 120° C., and the liquid ammonia (10 g/h) and hydrogen (40 mL/min)were introduced thereinto for 14 hours. After the liquid ammonia wasintroduced, the temperature and the pressure in the reaction tube werebrought back to normal, and then the catalyst was taken out to measure anickel crystallite diameter by an XRD device (MiniFlex600 manufacturedby Rigaku Corporation).

[Activity Test]

3% by mass of graphite was added to the calcined powder, which was thenmolded into 6 mmφ×6 mm by a tablet molding machine, and a reduced andstabilized product was produced in the same manner as described above.An activity (hydrogenation reaction) test was conducted as follows usingthe aforementioned reduced and stabilized product. In a 100 mL autoclavereaction vessel made of SUS, 2 g of the reduced and stabilized productwas placed, and then an inner temperature of a reaction tube was set at250° C. and 50% hydrogen/50% nitrogen was introduced at 20 mL/min for 10hours. Subsequently, the reaction vessel was filled with 10 g ofmeta-xylene (manufactured by Wako Pure Chemical Industries, Ltd.), 6.7 gof isophthalonitrile (manufactured by Tokyo Chemical Industry Co.,Ltd.), and 10 g of the liquid ammonia, and hydrogen was filled up to 10MPaG. After hydrogen was filled, a resultant in the vessel was heated at80° C. for 2 hours with stirring to allow the hydrogenation reaction toproceed in the vessel to produce meta-xylylenediamine (MXDA).

[Amount of Si Eluted of Diatomaceous Earth]

80 mL of a 10% Na₂CO₃ aqueous solution was added to 2 g of thediatomaceous earth, which was stirred at 60° C. for 2 hours. The amountof Si eluted contained in a resultant solution was measured by ICP-AES(Vista manufactured by Varian Inc.). Results are shown in Table 1.

In Table 2, an average amount of Si eluted of the diatomaceous earthused in each Example and Comparative Example was shown.

TABLE 1 Diatomaceous earth Kind Amount (%) of Si eluted Celite 503Calcined product 0.28 Diaful #110 Non-calcined product 1.2 Filter cellNon-calcined product 1.9

Example 1

In a 3 L three-neck flask, 17.5 g of filter cell (non-calcined product,manufactured by Imerys S.A.) and 17.5 g of celite 503 (calcined product,manufactured by Imerys S.A.) as diatomaceous earth, 283.2 g of nickelsulfate hexahydrate (manufactured by Wako Pure Chemical Industries,Ltd.) as a nickel source, and 1000 g of water were mixed at 25° C. toprepare slurry. Slurry was stirred at 300 rpm and heated to 70° C.

In another vessel, 202 g of sodium carbonate (manufactured by Wako PureChemical Industries, Ltd.) was dissolved in 1000 g of water to prepare aprecipitant. With a tube pump, the precipitant was poured into slurry at20 g/min. While pouring, slurry was maintained at a temperature of 70°C. and stirred. After the whole quantity of the precipitant was poured,a resultant was heated to 80° C. at 2° C./min and stirred for 2 hours toallow aging to proceed. After that, the produced slurry was subjected tofiltration under a reduced pressure using Nutsche (filter paper:Advantec 4A) to produce a filtered cake.

In a 3 L jug made of polypropylene, the filtered cake was placed and1000 g of pure water was added with stirring at 25° C. to transform thefiltered cake into slurry again, which was then washed in suspension andfiltered. Washing in suspension and filtration were performed repeatedlyuntil the electrical conductivity of filtrate reached 0.5 mS/cm or less.The filtered cake was dried at 110° C. for 12 hours using an electricdryer to produce a dried cake.

The dried cake was calcined at 380° C. for 5 hours in a calcinationfurnace to produce a catalyst calcined cake. This calcined cake waspulverized to produce a catalyst calcined powder.

The catalyst calcined powder was placed in a reaction tube made of SUShaving an inner diameter of 1.4 cm and reduction was performed at 400°C. for 10 hours using 50% hydrogen/50% nitrogen gas (60 mL/min). Afterthe reduction was stabilized, the reduced product was left to cool downto room temperature under the nitrogen atmosphere, and 1% oxygen/99%nitrogen gas (60 mL/min) was circulated for 4 hours and 4% oxygen/96%nitrogen gas (60 mL/min) was subsequently circulated for 2 hours forstabilization to produce a reduced and stabilized product. Measurementresults are shown in Table 2.

A crystallite diameter of nickel before and after the test changed from42 Å to 180 Å. A nickel crystallite after the test was 180 Å with asmall crystallite growth and high heat resistance.

Example 2

A nickel diatomaceous earth catalyst was produced in the same manner asin Example 1 except that the reduction conditions of the catalystcalcined powder were changed to 450° C. and 10 hours. Measurementresults are shown in Table 2.

Example 3

A nickel diatomaceous earth catalyst was produced in the same manner asin Example 1 except that the reduction conditions of the catalystcalcined powder were changed to 380° C. and 10 hours. Measurementresults are shown in Table 2.

Comparative Example 1

A nickel diatomaceous earth catalyst was produced in the same manner asin Example 1 except that the reduction conditions of the catalystcalcined powder were changed to 310° C. and 10 hours. Measurementresults are shown in Table 2.

Example 4

A nickel diatomaceous earth catalyst was produced in the same manner asin Example 1 except that the ratio of the filter cell/celite 503 in thediatomaceous earth was changed to 25% by mass/75% by mass. Measurementresults are shown in Table 2.

Example 5

A nickel diatomaceous earth catalyst was produced in the same manner asin Example 1 except that the ratio of the filter cell/celite 503 in thediatomaceous earth was changed to 75% by mass/25% by mass. Measurementresults are shown in Table 2.

Comparative Example 2

A nickel diatomaceous earth catalyst was produced in the same manner asin Example 1 except that the ratio of the filter cell in thediatomaceous earth was changed to 100% by mass and the aging time waschanged to 180 minutes. Measurement results are shown in Table 2.

Comparative Example 3

A nickel diatomaceous earth catalyst was produced in the same manner asin Example 1 except that the ratio of the filter cell/Diafil #110(non-calcined product, manufactured by Imerys S.A.) in the diatomaceousearth was changed to 50% by mass/50% by mass and the aging time waschanged to 180 minutes. Measurement results are shown in Table 2.

Example 6

A nickel diatomaceous earth catalyst was produced in the same manner asin Example 2 except that the aging time was changed to 100 minutes.Measurement results are shown in Table 2.

Example 7

A nickel diatomaceous earth catalyst was produced in the same manner asin Example 2 except that the aging temperature was changed to 70° C. andthe aging time was changed to 120 minutes. Measurement results are shownin Table 2.

Example 8

A nickel diatomaceous earth catalyst was produced in the same manner asin Example 2 except that the ratio of celite 503 in the diatomaceousearth was changed to 100% by mass. Measurement results are shown inTable 2.

Example 9

A nickel diatomaceous earth catalyst was produced in the same manner asin Comparative Example 2 except that the reduction temperature waschanged to 420° C. Measurement results are shown in Table 2.

Example 10

A nickel diatomaceous earth catalyst was produced in the same manner asin Comparative Example 3 except that the reduction temperature waschanged to 420° C. Measurement results are shown in Table 2.

Example 11

A nickel diatomaceous earth catalyst was produced in the same manner asin Comparative Example 2 except that the reduction temperature waschanged to 450° C. Measurement results are shown in Table 2.

Example 12

A nickel diatomaceous earth catalyst was produced in the same manner asin Comparative Example 3 except that the reduction temperature waschanged to 450° C. Measurement results are shown in Table 2.

TABLE 2 Calcined powder Dried Peak powder temperature Amount SpecificSpecific Surface of of Si Aging Aging surface surface area of H₂-TPReluted temperature time area area Ni (T) Support % ° C. min m²/g m²/gm²/g ° C. Example 1 Filter cell/Celite 1.1 80 120 288 245 32 317 503 =50/50 Example 2 Filter cell/Celite 1.1 80 120 288 245 32 317 503 = 50/50Example 3 Filter cell/Celite 1.1 80 120 288 245 32 317 503 = 50/50Comparative Filter cell/Celite 1.1 80 120 288 245 32 317 Example 1 503 =50/50 Example 4 Filter cell/Celite 0.7 80 120 252 191 23 324 503 = 25/75Example 5 Filter cell/Celite 1.5 80 120 257 250 32 360 503 = 75/25Comparative Filter cell 1.9 80 180 192 109 22 372 Example 2 ComparativeFilter cell/ 1.6 80 180 195 112 24 375 Example 3 Diafil # 100 = 50/50Example 6 Filter cell 1.9 80 100 251 194 35 315 Example 7 Filter cell1.9 70 120 255 198 37 311 Example 8 Celite 503 0.3 80 90 210 118 18 301Example 9 Filter cell 1.9 80 180 192 109 22 372 Example 10 Filter cell/1.6 80 180 195 112 24 375 Diafil # 100 = 50/50 Example 11 Filter cell1.9 80 180 192 109 22 372 Example 12 Filter cell/ 1.6 80 180 195 112 24375 Diafil # 100 = 50/50 Reduced and stabilized product Reduced andstabilized product Heat resistance test Weight loss CrystalliteCrystallite Activity Reduction Specific measured by diameter diametertest temperature surface TG at 400- (before (after MXDA (T) T′-T area600° C. test) test) Δ yield ° C. ° C. m²/g % Å Å Å % Example 1 400 83119 0.55 42 180 138 26 Example 2 450 133 105 0.1 60 100 40 22 Example 3380 63 122 1.8 40 250 210 28 Comparative 310 −7 189 4.0 25 390 365 9Example 1 Example 4 400 76 105 0.41 73 121 48 20 Example 5 400 40 1251.4 40 230 190 27 Comparative 400 28 68 3.1 105 342 237 15 Example 2Comparative 400 25 65 3.0 102 349 247 26 Example 3 Example 6 400 85 1181.2 35 185 150 27 Example 7 400 89 123 1.2 38 179 141 26 Example 8 40099 71 0.33 100 136 36 12 Example 9 420 48 67 1.8 107 259 152 16 Example10 420 45 64 1.9 105 261 156 27 Example 11 450 78 65 0.8 110 225 115 14Example 12 450 75 63 0.9 109 227 118 25

In Example 1, the crystallite diameter after the heat resistance test ofaround 180 Å was achieved by making the weight loss rate measured by TGat 400 to 600° C. 0.55%.

In Example 2, the crystallite diameter after the heat resistance test ofaround 100 Å was achieved by making the weight loss rate measured by TGat 400 to 600° C. 0.1%, and sintering resistance was improved.

In Example 3, the crystallite diameter after the heat resistance test ofaround 250 Å was achieved by making the weight loss rate measured by TGat 400 to 600° C. 1.8%.

In Examples 3, 4, and 5, and Comparative Examples 2 and 3, changingratio of the non-calcined product and the calcined product in thediatomaceous earth was able to make changes in the amount of Si elutedand the amount of weight loss measured by TG at 400 to 600° C. When theweight loss rate was above 2.0%, the crystallite diameter after the heatresistance test became more than 300 Å and the sintering resistance wasreduced.

In Examples 6 and 7, even though the diatomaceous earth was composed ofthe non-calcined product only, the amount of weight loss measured by TGat 400 to 600° C. was able to be reduced by changing the aging time andaging temperature of the precipitation in Comparative Example 2, and thesintering resistance was improved.

In Examples 8 to 12, the heat resistance of the catalyst was good.

The present application is based on the Japanese patent application(Japanese Patent Application No. 2015-215897) filed with the JapanPatent Office on Nov. 2, 2015, and the content thereof is herebyincorporated for reference.

1. A nickel diatomaceous earth catalyst having a weight loss ratemeasured by hydrogen-TG at 400 to 600° C. of 0.05 to 2.0%.
 2. The nickeldiatomaceous earth catalyst according to claim 1, wherein a nickelcrystallite diameter is 30 to 100 Å.
 3. The nickel diatomaceous earthcatalyst according to claim 1, wherein a change A in the nickelcrystallite diameter between before and after a heat resistance test is210 Å or less.
 4. The nickel diatomaceous earth catalyst according toclaim 1, wherein the nickel diatomaceous earth catalyst has a specificsurface area of 60 to 180 m²/g.
 5. A method for producing a nickeldiatomaceous earth catalyst by a precipitation method, comprising:adding an alkaline solution as a precipitant to a dispersion liquid inwhich diatomaceous earth and a salt of a nickel catalyst are mixed; andperforming a drying treatment, a calcination treatment, and a reductiontreatment, in this order, to obtain the nickel diatomaceous earthcatalyst, wherein the reduction treatment is performed at a peaktemperature +40° C. or more of a hydrogen-TPR measurement on a calcinedpowder produced by the calcination treatment.
 6. The method forproducing a nickel diatomaceous earth catalyst according to claim 5,wherein the reduction treatment is performed at the peak temperature+200° C. or less of the hydrogen-TPR measurement on the calcined powderproduced by the calcination treatment.
 7. A nickel diatomaceous earthcatalyst produced by the method according to claim
 5. 8. A method forproducing xylylenediamine, the method comprising hydrogenatingphthalonitrile in an ammonia solvent in the presence of the nickeldiatomaceous earth catalyst according to claim 1.